Tree crown delineation using detectreeRGB

Forest Modelling Regular Python

RoHub - FAIR Executable Research Object

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DOI

Context

Purpose

Accurately delineating trees using detectron2, a library that provides state-of-the-art deep learning detection and segmentation algorithms.

Modelling approach

An established deep learning model, Mask R-CNN was deployed from detectron2 library to delineate tree crowns accurately. A pre-trained model, named detectreeRGB, is provided to predict the location and extent of tree crowns from a top-down RGB image, captured by drone, aircraft or satellite. detectreeRGB was implemented in python 3.8 using pytorch v1.7.1 and detectron2 v0.5. Further details can be found in the repository documentation.

Highlights

  • detectreeRGB advances the state-of-the-art in tree identification from RGB images by delineating exactly the extent of the tree crown.

  • We demonstrate how to apply the pretrained model to a sample image fetched from a Zenodo repository.

  • Our pre-trained model was developed using aircraft images of tropical forests in Malaysia.

  • The model can be further trained using the user’s own images.

Contributions

Notebook

  • Sebastian H. M. Hickman (author), University of Cambridge, @shmh40

  • Alejandro Coca-Castro (reviewer), The Alan Turing Institute, @acocac

Modelling codebase

  • Sebastian H. M. Hickman (author), University of Cambridge @shmh40

  • James G. C. Ball (contributor), University of Cambridge @PatBall1

  • David A. Coomes (contributor), University of Cambridge

  • Toby Jackson (contributor), University of Cambridge

Modelling funding

The project was supported by the UKRI Centre for Doctoral Training in Application of Artificial Intelligence to the study of Environmental Risks (AI4ER) (EP/S022961/1).

Note

The authors acknowledge the authors of the Detectron2 package which provides the Mask R-CNN architecture.

Load libraries

import cv2
from PIL import Image
import os
import numpy as np
import urllib.request
import glob

# intake library and plugin
import intake
from intake_zenodo_fetcher import download_zenodo_files_for_entry

# geospatial libraries
import geopandas as gpd

from rasterio.transform import from_origin
import rasterio.features

import fiona

from shapely.geometry import shape, mapping, box
from shapely.geometry.multipolygon import MultiPolygon

# machine learning libraries
from detectron2 import model_zoo
from detectron2.engine import DefaultPredictor
from detectron2.utils.visualizer import Visualizer, ColorMode
from detectron2.config import get_cfg
from detectron2.engine import DefaultTrainer

# visualisation
import holoviews as hv
import geoviews.tile_sources as gts
import matplotlib.pyplot as plt

import hvplot.pandas
import hvplot.xarray

import warnings
warnings.filterwarnings(action='ignore')

hv.extension('bokeh', width=100)

Set folder structure

# Define the project main folder
notebook_folder = './notebook'

# Set the folder structure
config = {
    'in_geotiff': os.path.join(notebook_folder, 'input','tiff'),
    'in_png': os.path.join(notebook_folder, 'input','png'),
    'model': os.path.join(notebook_folder, 'model'),
    'out_geotiff': os.path.join(notebook_folder, 'output','raster'),
    'out_shapefile': os.path.join(notebook_folder, 'output','vector'),
}

# List comprehension for the folder structure code
[os.makedirs(val) for key, val in config.items() if not os.path.exists(val)]
[None, None, None, None, None]

Load and prepare input image

Fetch a GeoTIFF file of aerial forest imagery using intake

Let’s fetch a sample aerial image from a Zenodo repository.

# write a catalog YAML file
catalog_file = os.path.join(notebook_folder, 'catalog.yaml')

with open(catalog_file, 'w') as f:
    f.write('''
sources:
  sepilok_rgb:
    driver: rasterio
    description: 'NERC RGB images of Sepilok, Sabah, Malaysia (collection)'
    metadata:
      zenodo_doi: "10.5281/zenodo.5494629"
    args:
      urlpath: "{{ CATALOG_DIR }}/input/tiff/Sep_2014_RGB_602500_646600.tif"
      ''')
cat_tc = intake.open_catalog(catalog_file)
for catalog_entry in list(cat_tc):
    download_zenodo_files_for_entry(
        cat_tc[catalog_entry],
        force_download=False
    )
will download https://zenodo.org/api/files/271e78b4-b605-4731-a127-bd097e639bf8/Sep_2014_RGB_602500_646600.tif to /home/jovyan/notebook/input/tiff/Sep_2014_RGB_602500_646600.tif
tc_rgb = cat_tc["sepilok_rgb"].to_dask()

Inspect the aerial image

Let’s investigate the data-array, what is the shape? Bounds? Bands? CRS?

print('shape =', tc_rgb.shape,',', 'and number of bands =', tc_rgb.count, ', crs =', tc_rgb.crs)
shape = (4, 1400, 1400) , and number of bands = <bound method ImplementsArrayReduce._reduce_method.<locals>.wrapped_func of <xarray.DataArray (band: 4, y: 1400, x: 1400)>
array([[[36166.285 , 34107.22  , ..., 20260.998 , 11166.631 ],
        [32514.84  , 28165.994 , ..., 24376.36  , 21131.947 ],
        ...,
        [15429.493 , 16034.794 , ..., 19893.691 , 19647.646 ],
        [12534.722 , 14003.215 , ..., 21438.908 , 22092.525 ]],

       [[38177.168 , 36530.74  , ..., 19060.268 , 11169.006 ],
        [34625.227 , 30270.379 , ..., 21760.09  , 20796.621 ],
        ...,
        [17757.678 , 16818.102 , ..., 22538.023 , 23093.508 ],
        [13403.302 , 13354.489 , ..., 24638.21  , 25545.938 ]],

       [[13849.501 , 14158.603 , ...,  9385.764 ,  7401.662 ],
        [13252.31  , 13373.801 , ..., 12217.845 , 10666.252 ],
        ...,
        [13471.741 , 11533.697 , ...,  7536.6924,  8397.009 ],
        [13724.59  , 11057.722 , ...,  9778.8125, 11174.72  ]],

       [[65535.    , 65535.    , ..., 65535.    , 65535.    ],
        [65535.    , 65535.    , ..., 65535.    , 65535.    ],
        ...,
        [65535.    , 65535.    , ..., 65535.    , 65535.    ],
        [65535.    , 65535.    , ..., 65535.    , 65535.    ]]], dtype=float32)
Coordinates:
  * band     (band) int64 1 2 3 4
  * y        (y) float64 6.467e+05 6.467e+05 6.467e+05 ... 6.466e+05 6.466e+05
  * x        (x) float64 6.025e+05 6.025e+05 6.025e+05 ... 6.026e+05 6.026e+05
Attributes:
    transform:      (0.1, 0.0, 602480.0, 0.0, -0.1, 646720.0)
    crs:            +init=epsg:32650
    res:            (0.1, 0.1)
    is_tiled:       0
    nodatavals:     (-3.3999999521443642e+38, -3.3999999521443642e+38, -3.399...
    scales:         (1.0, 1.0, 1.0, 1.0)
    offsets:        (0.0, 0.0, 0.0, 0.0)
    AREA_OR_POINT:  Area> , crs = +init=epsg:32650

Save the RGB bands of the GeoTIFF file as a PNG

Mask R-CNN requires images in png format. Let’s export the RGB bands to a png file.

minx = 602500
miny = 646600

R = tc_rgb[0]
G = tc_rgb[1]
B = tc_rgb[2]
    
# stack up the bands in an order appropriate for saving with cv2, then rescale to the correct 0-255 range for cv2

# you will have to change the rescaling depending on the values of your tiff!
rgb = np.dstack((R,G,B)) # BGR for cv2
rgb_rescaled = 255*rgb/65535 # scale to image
    
# save this as png, named with the origin of the specific tile - change the filepath!
filepath = config['in_png'] + '/' + 'tile_' + str(minx) + '_' + str(miny) + '.png'
cv2.imwrite(filepath, rgb_rescaled)
True

Read in and display the PNG file

im = cv2.imread(filepath)
plot_input = plt.figure(figsize=(15,15))
plt.imshow(Image.fromarray(im))
plt.title('Input image',fontsize='xx-large')
plt.axis('off')
plt.show()
../../../_images/notebook_16_0.png

Modelling

Download the pretrained model

# define the URL to retrieve the model
fn = 'model_final.pth'
url = f'https://zenodo.org/record/5515408/files/{fn}?download=1'

urllib.request.urlretrieve(url, config['model'] + '/' + fn)
('./notebook/model/model_final.pth',
 <http.client.HTTPMessage at 0x7f11e4529580>)

Settings of detectron2 config

The following lines allow configuring the main settings for predictions and load them into a DefaultPredictor object.

cfg = get_cfg()

# if you want to make predictions using a CPU, run the following line. If using GPU, hash it out.
cfg.MODEL.DEVICE='cpu'

# model and hyperparameter selection
cfg.merge_from_file(model_zoo.get_config_file("COCO-InstanceSegmentation/mask_rcnn_R_101_FPN_3x.yaml"))
cfg.DATALOADER.NUM_WORKERS = 2
cfg.SOLVER.IMS_PER_BATCH = 2
cfg.MODEL.ROI_HEADS.NUM_CLASSES = 1

### path to the saved pre-trained model weights
cfg.MODEL.WEIGHTS = config['model'] + '/model_final.pth'

# set confidence threshold at which we predict
cfg.MODEL.ROI_HEADS.SCORE_THRESH_TEST = 0.15

#### Settings for predictions using detectron config

predictor = DefaultPredictor(cfg)

Outputs

Showing the predictions from detectreeRGB

outputs = predictor(im)
v = Visualizer(im[:, :, ::-1], scale=1.5, instance_mode=ColorMode.IMAGE_BW)   # remove the colors of unsegmented pixels
v = v.draw_instance_predictions(outputs["instances"].to("cpu"))
image = cv2.cvtColor(v.get_image()[:, :, :], cv2.COLOR_BGR2RGB)

plot_predictions = plt.figure(figsize=(15,15))
plt.imshow(Image.fromarray(image))
plt.title('Predictions',fontsize='xx-large')
plt.axis('off')
plt.show()
../../../_images/notebook_22_0.png

Convert predictions into geospatial files

To GeoTIFF

mask_array = outputs['instances'].pred_masks.cpu().numpy()

# get confidence scores too 
mask_array_scores = outputs['instances'].scores.cpu().numpy()

num_instances = mask_array.shape[0]
mask_array_instance = []
output = np.zeros_like(mask_array) 

mask_array_instance.append(mask_array)
output = np.where(mask_array_instance[0] == True, 255, output)
fresh_output = output.astype(float)
x_scaling = 140/fresh_output.shape[1]
y_scaling = 140/fresh_output.shape[2]
# this is an affine transform. This needs to be altered significantly.
transform = from_origin(int(filepath[-17:-11])-20, int(filepath[-10:-4])+120, y_scaling, x_scaling)

output_raster = config['out_geotiff'] + '/' + 'predicted_rasters_' + filepath[-17:-4]+ '.tif'

new_dataset = rasterio.open(output_raster, 'w', driver='GTiff',
                                height = fresh_output.shape[1], width = fresh_output.shape[2], count = fresh_output.shape[0],
                                dtype=str(fresh_output.dtype),
                                crs='+proj=utm +zone=50 +datum=WGS84 +units=m +no_defs',  
                                transform=transform)

new_dataset.write(fresh_output)
new_dataset.close()

To shapefile

# Read input band with Rasterio
    
with rasterio.open(output_raster) as src:
    shp_schema = {'geometry': 'MultiPolygon','properties': {'pixelvalue': 'int', 'score': 'float'}}    

    crs = src.crs
    for i in range(src.count):
        src_band = src.read(i+1)
        src_band = np.float32(src_band)
        conf = mask_array_scores[i]
        # Keep track of unique pixel values in the input band
        unique_values = np.unique(src_band)
        # Polygonize with Rasterio. `shapes()` returns an iterable
        # of (geom, value) as tuples
        shapes = list(rasterio.features.shapes(src_band, transform=src.transform))

        if i == 0:
            with fiona.open(config['out_shapefile'] + '/predicted_polygons_' + filepath[-17:-4] + '_' + str(0) + '.shp', 'w', 'ESRI Shapefile',
                            shp_schema) as shp:
                polygons = [shape(geom) for geom, value in shapes if value == 255.0]                                        
                multipolygon = MultiPolygon(polygons)
                        # simplify not needed here
                        #multipolygon = multipolygon_a.simplify(0.1, preserve_topology=False)                    
                shp.write({
                          'geometry': mapping(multipolygon),
                          'properties': {'pixelvalue': int(unique_values[1]), 'score': float(conf)} 
                           })
        else:
            with fiona.open(config['out_shapefile'] + '/predicted_polygons_' + filepath[-17:-4] + '_' + str(0)+'.shp', 'a', 'ESRI Shapefile',
                            shp_schema) as shp:
                polygons = [shape(geom) for geom, value in shapes if value == 255.0]                                        
                multipolygon = MultiPolygon(polygons)
                        # simplify not needed here
                        #multipolygon = multipolygon_a.simplify(0.1, preserve_topology=False)                    
                shp.write({
                          'geometry': mapping(multipolygon),
                          'properties': {'pixelvalue': int(unique_values[1]), 'score': float(conf)} 
                           })

Interactive map to visualise the exported files

Plot tree crown delineation predictions and scores

# load and plot polygons
in_shp = glob.glob(config['out_shapefile'] + '/*.shp')

poly_df = gpd.read_file(in_shp[0])

plot_vector = poly_df.hvplot(hover_cols=['score'], legend=False).opts(fill_color=None,line_color=None,alpha=0.5, width=800, height=600, xaxis=None, yaxis=None)
plot_vector

Plot the exported GeoTIFF file

# load and plot RGB image
r = tc_rgb.sel(band=[1,2,3])

normalized = r/(r.quantile(.99,skipna=True)/255)

mask = normalized.where(normalized < 255)

int_arr = mask.astype(int)

plot_rgb = int_arr.astype('uint8').hvplot.rgb(
    x='x', y='y', bands='band', data_aspect=0.8, hover=False, legend=False, rasterize=True, xaxis=None, yaxis=None, title='Tree crown delineation by detectreeRGB'
)

Overlay the prediction labels and image

Note we have some artifacts in the RGB image due to the transformations using the normalization procedure.

plot_predictions_interactive = plot_rgb * plot_vector
plot_predictions_interactive
OMP: Info #276: omp_set_nested routine deprecated, please use omp_set_max_active_levels instead.

Save plot

hvplot.save(plot_predictions_interactive, notebook_folder + '/interactive_predictions.html')

Summary

We have read in a raster, chosen a tile and made predictions on it. These predictions can then be transformed to shapefiles and examined in GIS software!

  • We made the predictions on the png using a pretrained Mask R-CNN model, detectreeRGB.

  • The outputs showed the model capability to detect and delineate tree crowns from aerial imagery.

  • We then extracted our predictions, added the geospatial location back in, and exported them as shapefiles including the confidence score assigned to each prediction by the model.

  • Visualised the predictions on an interactive map!

Citing this Notebook

Sebastian H. M. Hickman, and Alejandro Coca-Castro. “Tree crown delineation using detectreeRGB (Jupyter Notebook) published in the Environmental Data Science book.” ROHub. Mar 27 ,2022. https://doi.org/10.24424/2h9y-jn41.

Additional information

Codebase: version 1.0.0 with commit 16a5a1c

License: The code in this notebook is licensed under the MIT License. The Environmental Data Science book is licensed under the Creative Commons by Attribution 4.0 license. See further details here.

Contact: If you have any suggestion or report an issue with this notebook, feel free to create an issue or send a direct message to environmental.ds.book@gmail.com.

Last tested: 2023-03-20